DE102007015539A1 - Method for reconfiguring a communication network - Google Patents

Abstract

The invention relates to a method for reconfiguring a packet-switched communication network having a first network employing a first network protocol and a second network employing a second network protocol different from the first network protocol, in which the two networks are interconnected by at least three redundant data links, each of which only one is activated for user data exchange, wherein a master data link is activated by default and at least two slave data links are disabled by default, characterized by the following steps: detecting a failure of the master data link or a failure of a slave data link by one with the master Data link connected master bridge of the second network; Generating a first data packet to a second network, wherein the slave bridge is selected according to a preselected selection rule from the master bridge; Receiving and processing the erwobei the first data packet contains logical information, by which the at least partial execution of the first network protocol on a connected to the slave data link port of the slave bridge and activation of the slave data link by that on the port of the slave bridge executed first network protocol is triggered.

Description

The Invention is in the technical field of packet-switched Communication networks and relates to a method for reconfiguring a communication network in which LANs use different network protocols insert, are interconnected.

packet-switched Ethernet networks (LAN = Local Area Network) are used both in industrial environments as well as in office environment used, with the requirements placed on the networks are very different. Unlike the office environment, LANs have to in industrial everyday life under extreme conditions, such as electromagnetic interference fields, operate reliably at high operating temperatures and mechanical stresses. There the failure of a production plant and the associated downtime usually associated with high costs, it adds that in industrial applications the requirements for reliability are higher as in office environment.

For industrial For this reason, LANs use robust components that allow fast redundancy mechanisms, so as to reduce costs in the Error case possible to keep low. In addition, a ring topology for the network is usually chosen because this one in case of failure of a data link or a bridge fast reconfiguration time of less than 500 ms. As network protocols are used for industrial LANs usually Standard or proprietary network protocols based on the Ethernet standard used.

In contrast, are LANs in office environment mostly built in star or mesh topology and set as a network protocol Nowadays, RSTP (RSTP = Rapid Spanning Tree Protocol) according to the IEEE standard 802.1w.

In In practical use, ring-shaped industrial LANs with mesh Office LANs are over data links connected with each other. To the reliability of such connected To increase networks It is known to have two redundant data links between the two networks of which only a first redundant data link is enabled for data exchange between the two networks, while the second redundant data link is blocked and as a backup data link only activated in case of failure instead of the activated first data link becomes. The disadvantage here is the fact that the switching for activating the blocked second data link comparatively takes a lot of time and when using the standardized RSTP routines in the office LAN takes about 30 seconds.

Out that's why it desirable over one Method for reconfiguring a communication network connecting two LANs to dispose of the opposite the conventional one Method a faster reconfiguration in case of failure of the allows two LANs connecting data links.

These The object is achieved by a Method for reconfiguring a packet-switched communication network solved with the features of claim 1. Advantageous embodiments The invention are characterized by the features of the subclaims.

to solution the object is a method according to the invention for reconfiguring a packet switched communication network shown which one (by bridges switched) first network and a second network (bridged by bridges) that covers over at least three redundant data links are interconnected, of which only one for each the user data exchange is activated. Here and in the following will be as "redundant Data links "only connecting the two networks of the communication network Datalinks. The network nodes of the communication network are referred to here as "bridges". nevertheless In the sense of the invention, it may also be switches (switches = Multiport bridges) or other negotiating network nodes act.

at the at least three redundant data links are one presettable activatable or activated and for the user data exchange used master data link and by at least two presettable inactivatable or inactivated slave data links, which in case of failure of the master data link for the User data exchange can be used.

The redundant data links each connect a bridge of the first network and a bridge of the second network in terms of data technology. Every bridge of the second network can each have a separate bridge of connected to the first network. Equally it is possible that several bridges of the second network with different ports of a same bridge of the connected to the first network.

The bridge of the second network connected to the master data link is referred to here and below as a master bridge. The respective bridges of the second network connected to a slave data link are referred to here and below as slave bridges. Master and slave bridges of the second network can each be assigned individual path costs, with the master bridge having the lowest path costs of all redundant data link of the second network are assigned to associated bridges. The path costs assigned to the master and slave bridges of the second network may be stored in the master bridge in a corresponding data storage device. The path costs allocated to the master and slave bridges of the second network can in particular be transmitted by means of signals from the slave bridges to the master bridge, in particular based on the second network protocol.

The first network of the communication network can in particular as Office LAN in an office environment be installed. For The first network is a first network protocol for data exchange set up. The first network protocol will be in the first network preferably RSTP according to IEEE standard 802.1w, which is a logical topology in the form of a Spanning tree on the physical topology of the first network. The first network preferably has a meshed or star-shaped physical Topology on.

The second network of the communication network can in particular as Industrial LAN can be installed in an industrial environment and sets for the data exchange in particular based on the Ethernet standard second network protocol, which is a standard or proprietary network protocol can be. The network protocol of the second network is from the first network protocol, especially RSTP, different. The second Network preferably has an annular topology.

The inventive method for reconfiguring the communication network comprises the following steps:
Detecting a failure of the (default) activated master data link by the master bridge of the second network connected to the master data link. The failure of the master data link can be detected, for example, by a missing reception of a signal transmitted by the bridge of the first network connected to the master data link by the master bridge ("loss-of-signal"). The master bridge is provided for this purpose with a device for detecting a signal failure (hardware detector) of the data link. As a result, in particular a so-called hardware alarm of the master bridge can be triggered.

To Detecting the failure of the master data link by the master bridge: Generate a first data packet (N1) through the master bridge and transmit of the first data packet (N1) to one connected to a slave data link Slave bridge of the second Network. The master bridge selects the slave bridge of the second network for transmission of the first data packet according to a predefinable selection rule. The first data packet becomes advantageous (N1) by means of the second network protocol from the master bridge of the second network to the slave bridge of the second network.

To Sending the first data packet through the master bridge: receiving and processing the first data packet through the slave bridge, wherein the first data packet contains logical information by which the at least partial execution the first network protocol, in particular RSTP, on a with the slave data link connected port of the slave bridge triggered becomes.

To Activation of the first network protocol for the one with the slave data link connected port of the slave bridge: Activation of the slave data link by the first executed on the port of the slave bridge Netwerkprotokoll. Activation of the slave data link takes place preferably by running a handshake mechanism defined in RSTP between the RSTP port the slave bridge of the slave connected to the inactivated slave data link second network and one with the inactivated slave data link connected bridge the first network. Activation of the deactivated slave data link takes place here by means of RSTP standardized routines.

By the inventive method can advantageously a quick reconfiguration of the logical Topology in case of failure of a data link connecting the two LANs (Master data link) can be achieved.

In the event of a failure of a slave data link activated after failure of the master data link, the method according to the invention advantageously comprises the further steps:
Detecting the failure of the activated slave data link by a slave network bridge connected to the slave data link of the second network. The failure of the activated slave data link can be detected, for example, on the basis of a lack of reception of a signal transmitted by the bridge of the first network connected to the slave data link by the slave network of the second network. The Slav bridge is equipped for this purpose with a device for detecting a missing signal reception (hardware detector). As a result, in particular a hardware alarm of the Slav bridge can be triggered.

After detecting the failure of the slave data link through the slave bridge: generating a second data packet (N2) through the slave bridge and transmitting the second data packet (N2) to the master bridge. Advantageously, a transfer takes place of the second data packet from the slave network of the second network to the master bridge of the second network using the second network protocol.

To Sending the second data packet through the slave bridge: receiving and processing the second data packet (N2) by the master bridge, wherein the second data packet contains logical information which the master bridge over the Failure of the slave data link is informed.

After detecting the failure of the slave data link through the master bridge, the following steps are preferably performed:
Regenerating a first data packet (N1) by the master bridge and transmitting the first data packet (N1) to a slave network of the second network connected to a slave data link (not failed). In this case, the master bridge selects the slave bridge of the second network for transmission of the first data packet in accordance with the preselectable selection rule. Advantageously, the first data packet (N1) is transmitted by means of the second network protocol from the master bridge of the second network to the slave bridge of the second network.

Receive and processing the first data packet through the selected slave bridge, wherein the first data packet contains logical information through which the at least partial execution of the first network protocol, in particular RSTP, on a with the Slawe data link connected port of the slave bridge triggered becomes.

To Activation of the first network protocol on the with the Slawe data link connected port of the Slav Bridge: Activation of the slave data link by the first executed on the port of the Slav bridge Netwerkprotokoll. Activation of the slave data link takes place preferably by running a handshake mechanism defined in RSTP between the RSTP port the slave bridge connected to the inactivated slave data link of the second network and one with the inactive Slawe data link connected bridge of first network. Activation of the deactivated slave data link takes place here by means of RSTP standardized routines.

The Method for activating another inactivated slave data link in the event of failure of a slave data link activated after the failure of the master data link can for all slave data links the communication network are repeated.

By The above method can advantageously provide quick reconfiguration the logical topology in case of failure of one of the two LANs connecting Data links (slave data link) be achieved.

In Particularly advantageously, a selection of the Slav bridges to Activation of the Slav bridges associated slave data links according to the Slav bridges in each case assigned path costs. For this purpose are the master bridge and the Slav bridges the second network, respectively, path costs, in particular RSTP path costs, for example assigned by the network protocol. Particularly advantageous the master bridge assigned the lowest path costs.

To Failure of the master data link selects the Master Bridge to activate a slave data link, advantageously that slave bridge that in relation to the master bridge the next lowest Path costs are assigned. In case of failure of an activated Dials Slav data links the master bridge advantageous that Slav bridge the re the Slav Bridge of the failed slave data link has the next lowest path cost. In this way it can be ensured that the data connection between the two networks always the lowest possible Path costs has.

In a further advantageous embodiment of the method according to the invention, this comprises the following further steps:
Detecting the recovery of the failed master data link by the master bridge of the second network. Detection occurs, for example, by re-receiving signals, such as RSTP configuration frames, through the master bridge of the second network.

To Capture Master Link Restore by the Master Bridge: Generate a third data packet (N3) through the master bridge and transmit of the third data packet to the slave bridge of the activated slave data link. Advantageous the third data packet is transmitted to all Slav bridges. This will be the Slavic bridges the activated and inactivated slave data links via the Recovery of the master data link informed.

To Sending out the third data packet: receiving and processing the third data packet through the slave bridge (n), wherein the third data packet contains logical information, by which termination of the execution of the first network protocol, in particular RSTP, on the Slav Bridge or a termination of the Sending RSTP configuration frames through the slave bridge causes becomes.

Then: Activation of the master data link and inactivation of the activated slave data link.

hereby can advantageously a quick reconfiguration of the logical Topology when restoring the master data link.

In an advantageous embodiment of the method according to the invention, the following steps are performed to activate the restored master data link and to deactivate the second slave data link after detecting the restoration of the master data link by the master bridge:
At least partial execution of the first network protocol, in particular RSTP, on a master bridge connected to the master data link.

Preferably the master data link is activated by executing a implemented in RSTP handshake mechanism between those with the master data link directly connected bridges of the first and second networks. In addition, a forwarding takes place one while the handshake mechanism to activate the master data link generated RSTP configuration frame through the master bridge to the bridge connected to the activated slave data link first network, which deactivates the activated slave data link becomes.

termination the execution of the first network protocol, in particular RSTP, on which the Master data link connected port of the master bridge.

hereby can advantageously a particularly fast reconfiguration the logical topology when recovering the master data link in particular using routines implemented in RSTP be achieved.

The The invention further extends to a packet-switched as described above Communications network using a first network protocol first network and one different from the first network protocol second network protocol using second network, in which the two networks by at least three redundant data links are interconnected, of which only one for user data exchange is activated, being a master data link is activated by default and at least two slave data links are disabled by default. In the communication network are the bridges, in particular, the bridges associated with a slave data link, respectively arranged so that a method as described above is executable.

Of Furthermore, the invention extends to a master bridge of a as described above, the packet-switched communication network. About that In addition, the invention extends to a Slav bridge of a as described above, the packet-switched communication network.

The Invention will now be explained in more detail with reference to an embodiment, wherein Reference to the attached Drawings is taken. Show it:

1A - 1D schematic representations to illustrate an embodiment of the inventive method for reconfiguring a communication network.

In the 1A - 1D is shown schematically an embodiment of the communication network according to the invention. The total with the reference number 1 The designated communication network comprises a mesh-type, bridge-switched office LAN installed in an office environment 2 and a ring-bridged industrial LAN installed in an industrial environment 3 ,

The physical topology of the office LAN 2 includes four bridges 4 - 7 which are meshed with each other via respective point-to-point links (data links) in a meshed form. In the figures, the data links are shown by solid lines and otherwise unspecified.

In the office LAN 2 the network protocol RSTP standardized according to IEEE standard 802.1w is executed. By means of in the office LAN 2 Network Protocol RSTP is based on the physical topology of the office LAN specified by the bridges and data links 2 formed a logical topology in the form of a spanning tree, which is used exclusively for the exchange of user data packets. In the figures, the spanning tree is not specified.

The RSTP network protocol identifies all RSTP bridges and RSTP ports on the office LAN 2 unique identifiers (IDs) and path costs too. In RSTP, the bridges automatically cover the logical topology of the network by means of the data packets (data frames) passing through them, using the Layer 2 addresses of the network (MAC addresses, MAC = Medium Access Control) of the bridges.

In RSTP, the ports of the bridges can assume different states, in particular a state "blocking", in which only configuration frames, so-called BPDUs (BPDUs), are accepted by the bridges, a state "Listening", during which the active logical Topology is formed in the form of a spanning tree, a state "learning", during which a bridging table is composed of the read MAC addresses, a state "Forwarding", in which the ports forward user data, and a state "Disabled", in Ports neither receive nor forward payloads or BPDUs. Using the information contained in the BPDUs, the bridges can change the states of their ports.

Everyone Configuration Frame (BPDU) contains a Series of fields, such as a flag field to display or confirm a Topology change, a Rootbridge ID field to identify the root bridge with Specification of priority and ID, a path cost field specifying the path cost of the BPDU sending root bridge, a message age field (MessAge) for specifying the time period since transmission the BPDU, a MaxAge field specifying a time span after which Expiration the message is deleted is a Hello-time field for specifying the time span between regular configuration messages (Hello signals) of the root bridge, and a forward delay field, that's the wait after a change indicates the topology.

Around To form a loop-free logical topology are described in RSTP Four criteria for determining the highest priorities of the bridges or their ports used. These are: the smallest root-bridge ID, the lowest path cost to the root bridge, the smallest bridge ID and the smallest port ID.

Around a root bridge In RSTP, all ports of the bridges go after initialization (for example after restarting the network) first into the "blocking" state, with each bridge assuming that they themselves root bridge and a corresponding BPDU with its own ID as the root-bridge ID to the other bridges sends. Subsequently becomes the bridge with the lowest root-bridge ID to the root bridge selected. With identical root bridge ID is considered complementary Criterion used the lowest MAC address.

From the chosen one root bridge will be out afterwards Defines all network paths of the spanning tree via which a data exchange between the bridges in the communication network. To do this, the root bridge first sends BPDUs the other bridges. Every bridge then determines as root port a port that has the lowest path cost to the root bridge. In the case of the same path costs, the additional criterion is the port ID pulled up. Subsequently are determined based on the path costs Designate ports and the designated bridges of the spanning tree.

In RSTP shares the root bridge all bridges in the Spanning tree at regular intervals over one corresponding BPDU (Hello signal) with that she is still there. If such a hello signal is missing, for example due to the failure of a link or root bridge itself, is a reconfiguration of the communication network to determine a new spanning tree required. Because in this Time only BPDUs, d. H. Data packets to identify a new one Spannbaums transmitted be the communication network for this period of time for one User data exchange can not be used.

In RSTP also determines alternative ports that use BPDUs from other bridges block and provide an alternative route to the root bridge if the root port fails.

Further is a proposal / agreement handshake mechanism in RSTP between directly connected bridges implemented. about The Proposal / Agreement Handshake mechanism will send RSTP bridges from itself from BPDUs to the neighboring ones at predeterminable time intervals Bridges. RSTP specifies that a bridge loses its link to a neighboring bridge, if they do not receive BPDUs within a predefined period of time can. In this way, a failure of a link can be detected quickly become.

The topology of the industrial LAN 3 includes six bridges 8th - 13 which are annularly connected to each other via respective point-to-point data links. In the figures, the data links between the bridges are shown by a solid line and otherwise not designated.

In the industrial LAN 3 A proprietary network protocol based on the Ethernet standard is executed, which is provided by the RSTP network protocol of the office LAN 2 is different. The bridges 8th - 13 are therefore unlike the RSTP bridges of the office LAN 2 here and below as "proprietary bridges" of the industrial LAN 3 designated.

The office LAN 2 and the industrial LAN 3 are over three redundant data links 14 - 16 connected by data technology. These are a default activated master data link for the user data exchange 14 and two slave data links inactivated by default for user data exchange 15 . 16 ,

In 1A is shown an initial situation for carrying out the method according to the invention, in which the master data link 14 activated and the two slave data links 15 . 16 are inactivated. In 1A is the activated master data link 14 therefore represented by a solid line, while the two inactivated slave data links 15 . 16 are shown by broken lines. The two slave data links 15 . 16 serve as activatable redundant connections (back-up data links) between the two networks 2 . 3 ,

The master data link 14 is with an RSTP-executing RSTP port of the RSTP bridge 6 of the office LAN 2 and a proprietary port of the proprietary bridge employing the proprietary network protocol 8th ("Master bridge") of the industrial LAN 3 connected. A first slave data link 15 is with an RSTP-executing RSTP port of the RSTP bridge 7 of the office LAN 2 and a proprietary port of the proprietary bridge 9 of the industrial LAN 3 connected. A second slave data link 16 is with an RSTP-executing RSTP port of the RSTP bridge 5 of the office LAN 2 and a proprietary port of the proprietary bridge 13 of the industrial LAN 3 connected. In this respect, each data link connects between the two networks 2 . 3 a bridge of one network with a separate bridge of the other network.

Both with the master data link 14 Connected ports are enabled, especially the RSTP port of the RSTP bridge 6 of the office LAN 2 in its state "Forwarding" is located. To block the first slave data link 15 is the one with the first slave data link 15 connected RSTP port of the RSTP bridge 7 of the office LAN 2 put into its state "blocking". To block the second slave data link 16 is the one with the second slave data link 16 connected RSTP port of the RSTP bridge 5 of the office LAN 2 put into its state "blocking".

In the communication network shown in the figures 1 are the RSTP bridges of the office LAN 2 and the one with the office LAN 2 via the data links 14 - 16 directly connected bridges 8th . 9 . 13 of the industrial LAN 3 Assigned RSTP path costs. In the with the master data link 14 connected master bridge 8th of the industrial LAN 3 are the path costs of all with the office LAN 2 directly connected industrial LAN bridges 3 stored in a data storage device. Alternatively, the path costs of using the office LAN 2 directly connected slave bridges of the industrial LAN 3 via messages generated by the slave bridges (data packets), in particular based on the proprietary network protocol of the industrial LAN 3 to the master bridge 8th be sent.

In 1B a situation is shown in which, starting from the in 1A illustrated situation with activated master data link 14 this has failed for the user data transmission. In 1B is the failed master data link 14 represented by a broken line. The failure of the activated master data link 14 is by the two through the master data link 14 connected bridges by a missing signal reception ("loss of signal") by a corresponding means for detecting a missing signal reception (hardware detector) detected. In the master bridge 8th of the industrial LAN 3 this triggers a hardware alarm, as a result of which a first data packet N1 from the master bridge 8th is generated.

Then choose the master bridge 8th under the two Slav bridges 9 . 13 , those assigned the smaller RSTP path cost. In the embodiment of 1B this is the Slav bridge 9 the first slave data link 15 ,

Subsequently, the master bridge sends 8th using the proprietary network protocol of the industrial LAN, the first data packet N1 via the corresponding data link of the ring-shaped industrial LAN 3 to those with the first slave data link 15 connected Slav bridge 9 , The first data packet N1 contains logical information through which the slave bridge 9 is informed that the master link 14 failed for the user data exchange. For this purpose, for example, a "failed master data link" flag is set in the first data packet N1.

By receiving and processing the first data packet N1 through the Slav bridge 9 becomes a partial or complete execution of the network protocol RSTP according to IEEE standard 802.1w on that port of the Slav bridge 9 triggered with the first slave data link 15 connected is. As a result, the Slav bridge appears 9 of the industrial LAN 3 the office LAN 2 opposite as RSTP bridge.

The Slav Bridge 9 of the industrial LAN 3 Here is a highest bridge ID, that is the lowest priority of all RSTP bridges of the office LAN 2 assigned, which can be ensured that the Slav bridge 9 in the formation of a spanning tree of the office LAN 2 not undesirable as a new root bridge is chosen.

Subsequently, the Slav bridge now provided with an RSTP port is generated 9 of the industrial LAN 3 a first RSTP configuration frame (RSTP-BPDU1) and sends the first RSTP configuration frame through its RSTP port over the first slave data link 15 to the RSTP bridge connected to the first slave data link 7 of the office LAN 2 , As part of the handshake mechanism implemented in RSTP, the RSTP configuration frame RSTP-BPDU1 is a proposal for activating the with the first slave data link 15 connected (blocked) RSTP ports of the RSTP bridge 7 of the office LAN 2 ,

After receiving and processing the first RSTP configuration frame through the RSTP bridge 7 of the office LAN 2 generates the RSTP bridge 7 a second RSTP configuration frame (RSTP-BPDU2) and sends the second RSTP configuration frame to the slave bridge 9 of the industrial LAN 3 , The second RSTP configuration frame is another proposal.

After receiving and processing the second RSTP configuration frame through the Slav bridge 9 This generates a third RSTP configuration frame (RSTP-BPDU3) and sends the third RSTP configuration frame to the RSTP bridge 7 of the industrial LAN 3 , The third RSTP configuration frame is an agreement. Upon receipt of the consent message, the RSTP port of the RSTP bridge becomes 7 the first slave data link 15 put into its "Forwarding" state, causing the blocked first slave data link 15 is put into its active state, which allows a user data exchange between the two networks. This is in 1B by a solid line for the first slave data link 15 illustrated. The handshake mechanism for activating the first slave data link 15 connected blocked RSTP ports complies with the IEEE standard 802 .1w standardized routines.

In 1C another situation is shown in which the activated for data transmission first slave data link 15 has failed. The failure of the first slave data link 15 is through the with the first slave data link 15 connected Slav bridge 9 detected, for example, by a hardware detector detecting the lack of configuration of BPDUs coming from the bridge 7 of the office LAN 2 can be sent out. In the slave bridge 9 of the industrial LAN 3 this triggers a hardware alarm, as a result of which a second data packet N2 from the slave bridge 9 is generated.

Subsequently, the slave bridge sends 9 using the proprietary network protocol of the industrial LAN 3 the second data packet N2 via the corresponding data link of the ring-shaped industrial LAN 3 to those with the master data link 14 connected master bridge 8th , The second data packet N2 contains logical information through which the master bridge 8th is informed that the first slave data link 15 failed for the user data exchange. For this purpose, for example, a "failed slave data link" flag is set in the second data packet N2.

In the master bridge 8th of the industrial LAN 3 triggers the detection of the failure of the first slave data link 15 by means of the second data packet from a hardware alarm, as a result again a first data packet N1 from the master bridge 8th is generated.

Then choose the master bridge 8th the next slave bridge 13 for transmission of the generated first data packet N1. The master bridge 8th selects such a slave bridge with respect to the failed with the first slave data link 15 connected slave bridge 9 the next lower RSTP path costs are assigned, here the slave bridge 13 ,

Subsequently, the master bridge sends 8th using the proprietary network protocol of the industrial LAN, the first data packet N1 via the corresponding data link of the ring-shaped industrial LAN 3 to the one with the second slave data link 16 connected slave bridge 13 , The first data packet N1 contains logical information through which the slave bridge 13 is informed that the master data link 14 failed for the user data exchange. For this purpose, for example, a flag "Failed master data link" is set in the first data packet N1.

By receiving and processing the first data packet N1 through the Slav bridge 13 of the second slave data link 16 becomes a partial or complete execution of the network protocol RSTP according to IEEE standard 802.1w on that port of the Slav bridge 13 triggered with the second slave data link 16 connected is. This will cause the slave bridge to appear 13 of the industrial LAN 3 the office LAN 2 opposite as RSTP bridge.

Subsequently, the Slav bridge now provided with an RSTP port is generated 13 of the industrial LAN 3 a first RSTP configuration frame (RSTP-BPDU1) and sends the first RSTP configuration frame through its RSTP port over the second slave data link 16 to the RSTP bridge connected to the second slave data link 5 of the office LAN 2 , As part of the handshake mechanism implemented in RSTP, the RSTP configuration frame RSTP-BPDU1 is a proposal for activating the second slave data link 16 connected (blocked) RSTP ports of the bridge 5 of the office LAN 2 ,

After receiving and processing the first RSTP configuration frame through the RSTP bridge 5 of the office LAN 2 generates the RSTP bridge 5 a second RSTP configuration frame (RSTP-BPDU2) and sends the second RSTP configuration frame to the slave bridge 13 of the industrial LAN 3 , The second RSTP configuration frame men is another proposal (proposal).

After receiving and processing the second RSTP configuration frame through the Slav bridge 13 This generates a third RSTP configuration frame (RSTP-BPDU3) and sends the third RSTP configuration frame to the bridge 5 of the industrial LAN 3 , The third RSTP configuration frame is an agreement. Upon receipt of the consent message, the RSTP port of the bridge becomes 5 of the second slave data link 16 put into its "forwarding" state, causing the blocked second slave data link 16 is put into its active state, in which a user data exchange between the two networks is enabled. This is in 1C by a solid line for the second slave data link 16 illustrated. The handshake mechanism for activating the second slave data link 16 connected blocked RSTP ports complies with IEEE standard 802.1w standardized routines.

In 1D another situation is illustrated in which the master data link 14 recovered after his failure. The with the master data link 14 connected master bridge 8th of the industrial LAN 3 recognizes via re-incoming signals, which of the with the master data link 14 connected bridge 6 of the office LAN 2 sent out, the recovered master data link 14 , The detection of the signals is carried out by the hardware detector, which has also detected the absence of signals. This triggers the generation of a third data packet N3 by the master bridge 8th ,

The third data packet N3 is then used by means of the proprietary network protocol of the industrial LAN 3 via the corresponding data links of the industrial LAN 3 to the slave bridges 9 . 13 Posted. The third data packet N3 becomes the Slav bridges 9 . 13 informed that the master data link 14 is restored. For this purpose, for example, a "failed master data link" flag is deleted in the third data packet N3.

By receiving and processing the third data packet N3 through the Slav bridges 9 . 13 in each case a termination of the execution of the network protocol RSTP is triggered for each connected to the slave data link port of the slave bridges. The ports of the Slav bridges connected to the slave data links 9 . 13 Thus, each from an RSTP port to one of the proprietary network protocol of the industrial LAN 3 changed controlled port. The sla ve bridges 9 . 13 appear on the office LAN 2 no more than RSTP bridges.

The capture of the recovered master data link 14 through the master bridge 8th further triggers the partial or complete execution of the network protocol RSTP according to IEEE standard 802.1w (only) on that port of the master bridge 8th that with the blocked master data link 14 connected is. This will cause the master bridge to appear 8th the office LAN 2 opposite as RSTP bridge.

The master bridge, now equipped with an RSTP port, then generates 8th of the industrial LAN 3 a first RSTP configuration frame (RSTP-BPDU1) and sends the first RSTP configuration frame through its with the master data link 14 connected to the RSTP port with the master data link 14 connected RSTP bridge 6 of the office LAN 2 , This is in 1D illustrated by an arrow. The configuration frame RSTP-BPDU1 is a proposal (proposal) within the framework of the handshake mechanism implemented in RSTP.

After receiving and processing the first RSTP configuration frame through the RSTP bridge 6 of the office LAN 2 generates the RSTP bridge 6 a second RSTP configuration frame (RSTP-BPDU2) and sends the second RSTP configuration frame to the master bridge 8th , This is in 1D also illustrated by an arrow. The second RSTP configuration frame is a proposal for activation of the master data link 14 connected, blocked RSTP ports of the bridge 6 of the office LAN 2 ,

Upon receipt and processing of the second RSTP configuration frame, the master bridge generates 8th of the industrial LAN 3 a third RSTP configuration frame (RSTP-BPDU3) and sends the third RSTP configuration frame through its with the master data link 14 connected to the RSTP port with the master data link 14 connected RSTP bridge 6 of the office LAN 2 , This is in 1D illustrated by an arrow.

The third RSTP configuration frame is an agreement to activate with the master data link 14 connected, blocked RSTP ports of the bridge 6 of the office LAN 2 ,

The blocked RSTP port will then be the one with the master data link 14 connected RSTP bridge 6 of the office LAN 2 put into its state "Forwarding". This will cause the blocked master data link 14 put into its active state, allowing a user data exchange between the two networks 2 . 3 via the master data link 14 is possible.

The above-mentioned handshake mechanism mus to activate with the master data link 14 connected, blocked RSTP ports of the RSTP bridge 6 of the office LAN 2 is done through routines standardized in the IEEE 802.1w standard.

Furthermore, the master bridge 8th of the industrial LAN 3 received second RSTP configuration frame (RSTP-BPDU2) unchanged to those with the second slave data link 16 connected slave bridge 13 forwarded. A forwarding is done by the proprietary network protocol of the industrial LAN 3 , Upon receipt, the one with the second slave data link forwards 16 connected slave bridge 13 the second RSTP configuration frame (RSTP-BPDU2) unchanged to that with the second slave data link 16 connected RSTP bridge 5 of the office LAN 2 further. Thereupon the RSTP port located in the "Forwarding" state becomes the one with the second slave data link 16 connected RSTP bridge 5 of the office LAN 2 placed in its "blocking" state, leaving the second slave data link 16 is inactivated.

Subsequently, after activating the master data link 14 and after passing the second RSTP configuration frame (RSTP-BPDU2) through the master bridge 8th of the industrial LAN 3 , terminates the execution of the network protocol RSTP for the master data link 14 connected port of the master bridge 8th triggered. The one with the master data link 14 connected port of the master bridge 8th Thus, from an RSTP port, it becomes one of the industrial LAN's proprietary network protocol 3 changed controlled port. The master bridge 8th then appears on the office LAN 2 no more than an RSTP bridge.

By the inventive method can in a simple way, a reconfiguration of a multi-redundant Data connection using two different network protocols Networks can be achieved. In particular, an RSTP network with a another network in ring topology multi-redundant connected with the reconfiguration times for reconfiguring a the two networks connecting data links are very short. A restriction on a single redundant backup data link is not necessary. This allows a data connection between the two networks even with multiple failures maintained by the two networks connecting data links become. The effort to configure such a communication network is low.

Claims (19)

Method for reconfiguring a packet-switched communication network ( 1 ) with a first network employing a first network protocol ( 2 ) and a second network employing a second network protocol different from the first network protocol ( 3 ) in which the two networks are interconnected by at least three redundant data links ( 14 . 15 . 16 ) are interconnected, of which only one is activated for user data exchange, wherein a master data link ( 14 ) is activated by default and at least two slave data links ( 15 . 16 ) are disabled by default, characterized by the following steps: detecting a failure of the master data link ( 14 ) or a failure of an activated slave data link ( 15 . 16 ) by one with the master data link ( 14 ) connected master bridge ( 8th ) of the second network ( 3 ); Generating a first data packet (N1) by the master bridge (FIG. 8th ) and transmitting the first data packet (N1) to a slave bridge of the second network connected to a slave data link, the slave bridge being selected according to a preselected selection rule from the master bridge; Receiving and processing of the first data packet (N1) by the selected slave bridge, the first data packet containing logical information, by which the at least partial execution of the first network protocol on a connected to the slave data link port of the slave bridge and an activation of the slave data link is triggered by the first network protocol executed on the port of the slave bridge. Method according to Claim 1, in which the first data packet (N1) is transmitted by means of the second network protocol from the master bridge (N1). 8th ) of the second network ( 3 ) is transmitted to a slave bridge of the second network. Method according to one of Claims 1 to 2, in which a detection of the failure of the master data link ( 14 ) through the master bridge connected to the master data link ( 8th ) due to one of the master bridge ( 8th ) no longer received signal from that with the master data link ( 14 ) connected bridge ( 6 ) of the first network ( 2 ) he follows. Method according to one of Claims 1 to 3, characterized by the steps of: detecting a failure of an activated slave data link by a slave network of the second network connected to the slave data link; - generating a second data packet (N2) through the slave bridge and transmitting the second data packet (N2) to the master bridge; Receiving and processing the second data packet (N2) by the master bridge, wherein the second data packet contains logical information by which the master bridge is informed about the failure of the activated slave data link ( 15 ) is informed. The method of claim 4, wherein the second Data packet (N2) by means of the second network protocol from the Slav bridge of the second network to the master bridge of the second network becomes. Method according to one of Claims 1 to 5, in which the signals from the master bridge ( 8th ) selected slave bridge for transmission of the first data packet (N1) according to the Slav bridges each assigned path costs is selected. Method according to claim 6, in which the master bridge ( 8th ) in case of failure of the master data link ( 14 ) to activate a slave data link Slav bridges with the lowest path costs are selected. Method according to one of claims 1 to 7, wherein the first network protocol RSTP according to IEEE standard 802.1w is. The method of claim 8, wherein the activation a slave data link by executing one implemented in RSTP Handshake mechanism between the bridges directly connected to the slave data link takes place. Method according to one of claims 1 to 9, characterized by the following steps: - detecting the restoration of the failed master data link ( 14 ) through the master bridge ( 8th ); Generating a third data packet (N3) by the master bridge (FIG. 8th ) and transmitting the third data packet (N3) at least to the slave bridge connected to an activated slave data link; Receiving and processing the third data packet (N3) through the Slav bridge ( 13 ), wherein the third data packet contains logical information by which an at least partial termination of the execution of the first network protocol, in particular RSTP, is effected on the Slav bridge or a termination of the transmission of RSTP configuration frames by the Slav bridge, - activation of Master data links ( 14 ), - deactivating the activated Slawe data link. Method according to Claim 10, in which the third data packet (N3) is transferred by means of the second network protocol from the master bridge of the second network to a slave bridge ( 8th ) of the second network ( 3 ) is transmitted. A method according to any one of claims 10 to 11, wherein the third data packet (N3) to all with a slave data link transmitted connected Slav bridges becomes. Method according to one of claims 10 to 12, wherein after detecting the restoration of the master data link ( 16 ) an at least partial execution of the first network protocol, in particular RSTP, on one with the master data link ( 14 ) connected to the master bridge ( 8th ) he follows. Method according to Claim 13, in which activation of the master data link ( 14 ) by executing a handshake mechanism implemented in RSTP between those with the master data link ( 14 ) directly connected bridges ( 6 . 8th ) he follows. The method of claim 14, wherein inactivating the slave data link ( 16 ) forwarding by the master bridge a configuration frame generated during the handshake mechanism ( 8th ) to the with the activated Slawe data link ( 16 ) connected bridge ( 5 ) of the first network ( 2 ) he follows. Method according to one of Claims 13 to 15, in which, after activation of the master data link ( 14 ) termination of the execution of the first network protocol, in particular RSTP, on which the master data link ( 14 ) connected to the master bridge ( 8th ) he follows. Packet-switched communication network ( 1 ), with a first network employing a first network protocol ( 2 ) and a second network employing a second network protocol different from the first network protocol ( 3 ), in which the two networks are interconnected by at least three redundant data links, of which only one is activated for user data exchange, wherein a master data link ( 14 ) is activated by default and at least two slave data links ( 15 . 16 ) are inactivated by default, in which the bridges of each are arranged so that a method according to any one of claims 1 to 16 is executable. Master Bridge a packet-switched communication network according to claim 17th Slav Bridge a packet-switched communication network according to claim 17th